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Hearing The Ability to Sense Vibrations in the Air

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Title: PowerPoint Presentation Author: cristina fernandez-valle Last modified by: cfernand Created Date: 3/2/2004 2:20:04 PM Document presentation format – PowerPoint PPT presentation

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Title: Hearing The Ability to Sense Vibrations in the Air


1
Hearing The Ability to Sense Vibrations in the
Air
  • Process known as
  • Mechanosensory Transduction

2
Mechanosensory Transduction
  • The process by which mechanical energy in the
    vibration of sound waves traveling through air
    are converted into electrical signals that the
    brain can process and understand

3
Sound
  • Audible variations in air pressure
  • Objects that move make sound as the object moves
    toward a patch of air it compresses (increases
    density of air molecules)
  • Object moving away from a patch of air it
    rarefies (makes molecules less dense)
  • Speed of sound travels at 343 m/sec 767 mph

4
Sensitivity to Sound
  • At threshold of hearing, the air molecules are
    moving 10 picometers.
  • Hearing more sensitive than vision

5
Sound waves
  • Sound waves are periodic changes in air pressure
  • Sound is a sine wave moving up and down

6
Sonic Boom
  • aircraft traveling through the atmosphere
    continuously produces air-pressure waves similar
    to the water waves caused by a ship's bow.
  • When the aircraft exceeds the speed of sound,
    these pressure waves combine and form shock waves
    which travel forward from the generation or
    "release" point.
  • The sound heard on the ground as a "sonic boom"
    is the sudden onset and release of pressure after
    the buildup by the shock wave or "peak
    overpressure."

7
4 Features of Sound Waves
  • Waveformamplitude vs time
  • Phasecompletion of 1 cycle
  • Amplitudeintensityloudness decibels dB
  • Frequencycycles/secondpitch

8
Frequency of soundwave
  • is the number of compressed/rarefied air patches
    that move past ear/second.
  • Audible range 20 Hz-20,000 Hz
  • Frequency of sound wave determines the Pitch
  • Low organ note20Hz high piccolo note is 10K Hz
  • Double the frequency raise the pitch one octave

9
Frequency of Sound Wave
  • Humans hear 20 cycles/sec Hz to 20,000 Hz
  • Greatest sensitivity is 1000-4000 Hz
  • Each spiral ganglion sensory neuron having a
    synapse with a hair cell is tuned in or most
    sensitive to a particular frequency

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WaveFrequency Pitch
  • Ultrasound above 20KHz
  • Infrasound below 20 Hz
  • Unheard sounds can have subconscious effects
    causing dizziness, headache, nausea (carsick) due
    to low frequency sound of car at high speed
  • High intensity low frequency sound can damage
    internal organs by resonating the body cavity

12
WaveHeight Intensity/Loudness
  • Difference in pressure between the peak
    compressed and peak rarefied patch of air
  • Determines loudness of sound expressed in
    decibels
  • Loud sounds have higher intensity
  • To double loudness, intensity increases 10fold

13
Loudness-decibels
  • Logarithmic scale
  • 20dBwhisper
  • 65 dBnormal speaking voice
  • 100dBnear jet engine
  • 120dBpain
  • Is represented by the height amplitude sound wave
  • Encoded by number of neurons activated not height
    of spike or number of spikes/time

14
Phase
  • Used to locate sound in space by comparing the in
    and out of phase waveforms

15
Anatomy of the EAR
  • Mechanosensory cellshair cells
  • Located within the cochleaa spiral shaped bony
    enclosure filled with fluid.
  • Air vibrations impact the tympanic membrane
    stretched across the ear canal.
  • Transmitted to cochlea through 3 bones in middle
    ear

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18
Ossicle Amplification
  • Ossicles amplify the sound wave in air to produce
    a force on the oval window 5 times greater than
    on the tympanic membrane so that the fluid in the
    cochlea is moved
  • stapes transduces air waves into water waves
    since the cochlea is a fluid filled chamber
  • 1000 ft/sec sound through air
  • 5000 ft/sec sound through water

19
Oval Window
  • Oval window connection of middle ear stapes bone
    with opening of cochlea
  • Is a flexible membrane

20
Cochlea
  • Separated into 2 regions by the basilar membrane.
  • A pressure wave reaches the oval window and
    pushes it inward and increases pressure above the
    basilar membrane
  • Basilar membrane moves downward as pressure is
    released by bulging out the round window at base
    of cochlea

21
Cochlear Compartments
  • Scala vestibuli is connected to oval window where
    sound waves enter cochlea
  • Scale tympani is compartment connected to round
    window
  • Intervening compartment is scala media that is
    bounded by basilar and vestibular membranes

22
Basilar Membrane Architecture
  • Narrow at base near oval window
  • Wide at apex
  • Hair cells sit along the basilar membrane, have
    cilia will depolarize to different extents in
    response to frequency of sound wave
  • High frequency hair cells respond maximally to
    high frequency sound with high frequency
    oscillation of membrane potential

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24
Basilar Membrane
  • Moves up and down in response to waves of
    pressure impinging on oval window and transmitted
    through to round window.
  • Hair cells sit atop the basilar membrane
  • Hair cells connect to sensory neurons that live
    in spiral ganglion inside cochlea
  • Axon travels to CNS through auditory nerve ie CN8

25
Organ of Corti
  • Contains hair cells and rest on the basilar
    membrane and move up and down with sound waves
  • Composed of outer and inner hair cells
  • Three rows of outer hair cells, 1 row of inner
    hair cells. Exist at ratio of 51 or 20K to 4K

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27
Hair Cells
  • Mechanoreceptors for vibration
  • Have cilia which are deflected by vibrations
  • Deflection change membrane potential of hair cells

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29
George Van Bekesy
  • Nobel Prize in 1961

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34
Ion Channels
  • Changes in membrane potential of hair cells is
    caused by movement of cilia that changes ion
    permeability
  • Cilia on hair cells are tethered to each other at
    the tips by connecting filaments that act like
    springs that transmit tension to cation channels
    in membrane of cilia

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37
NT release
  • Potassium channels open
  • Potassium comes in and depolarizes membrane
  • Voltage sensitive calcium channels open
  • Increased calcium causes NT release onto spiral
    ganglion neurite

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39
Cochlear Fluid
  • Perilymph Same ionic
  • In Scala vestibuli and tympani
  • Composition as CSF
  • 7mM K
  • 140mM Na
  • Bathes the hair cells
  • Endolymph
  • In Scala Media
  • Hi K concentration
  • 150mM K
  • 1mM Na
  • Bathes stereocilia of hair cells
  • Inward K flux leads to depolarization

40
Outer Hair Cells
  • Outer are larger with more cilia
  • Embedded in overlying membrane ka tectorial
    membrane
  • Cilia are deflected by shearing forces generated
    by movements of basilar and tectorial membranes

41
Function of Outer Hair Cell
  • To amplify movement of tectorial membrane so that
    inner hair cell will respond more strongly
  • Outer hair cells do this by increasing and
    decreasing their length thus amplifying movement
    of basilar membrane at area that matches the
    frequency of sound

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43
Inner Hair Cells
  • Are not directly connected to tectorial membrane
  • Cilia move in response to motion of fluid within
    cochlea transmit caused by outer hair cells

44
Functions of Inner Hair Cell
  • Afferent cells that transmit information to the
    sensory neuron
  • 90 of all synapses with sensory neurons occur
    with inner hair cells
  • 1 inner hair cell can connect to 20 spiral
    ganglion neurons

45
Sensory Neuron Connections
  • Almost all spiral sensory ganglion neurons
    contact inner hair cells
  • 15K HC 30K SGN
  • 201 ratio of inner cells to outer cells
    contacted by neurons
  • 20 outer hair cells synapse with 1 neuron whereas
    1 inner hair cell contact 5-10 neurons
  • More information reaches CNS from inner hair cell

46
Differences Between Outer and Inner Hair Cells
  • Outer HC are larger than Inner HC have more
    cilia that attach to tectorial membrane above
  • Inner hair cells do not directly touch the
    tectorial membrane and fluid alone causes cilia
    movement

47
Active Movements
  • Hair cells elongate and shorten in height to
    amplify basilar membrane movements
  • Depolarization shortens the hair cell
  • Hyperpolarization lengthens hair cell
  • Involves changes in actin filament lengths and is
    not well understood

48
Contractions of Hair Cells
  • Amplifies movement of basilar membrane

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50
Damage to Ear
  • Mechanical or Neural
  • Mechanicaldamage to tympanic membrane or
    ossification of middle ear bones
  • Neuralshearing off or sticking of hair cell
    cilia and damage to auditory nerve CN8
  • Birds regenerate hair cells humans do not

51
END
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55
Hearing Sound
  • Sound is a sine wave moving up and down
  • Frequency of the sine wave determines the pitch
    of sound
  • Each spiral ganglion nerve axon is tuned to
    respond to a particular frequency maximally and
    less well to higher and lower frequencies

56
Afferent Connections
  • Refer to hair cells sending info to spiral
    ganglion neurons that bring info to the CNS
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